The Adh in Drosophila: chromosomal location and restriction analysis in species with different phylogenetic relationships

Origin and evolution of a chimeric fusion gene in Drosophila subobscura, D. madeirensis and D. guanche

An understanding of the mutational and evolutionary mechanisms underlying the emergence of novel genes is critical to studies of phenotypic and genomic evolution. Here we describe a new example of a recently formed chimeric fusion gene that occurs in Drosophila guanche, D. madeirensis, and D. subobscura. This new gene, which we name Adh-Twain, resulted from an Adh mRNA that retrotransposed into the Gapdh-like gene, CG9010. Adh-Twain is transcribed; its 5' promoters and transcription patterns appear similar to those of CG9010. Population genetic and phylogenetic analyses suggest that the amino acid sequence of Adh-Twain evolved rapidly via directional selection shortly after it arose. Its more recent history, however, is characterized by slower evolution consistent with increasing functional constraints. We present a model for the origin of this new gene and discuss genetic and evolutionary factors affecting the evolution of new genes and functions.

Colonization of America by Drosophila subobscura: association between Odh gene haplotypes, lethal genes and chromosomal arrangements

The colonization of America by Drosophila subobscura has been a unique exper iment in nature that has allowed us to explore the effects of evolution on a continental scale. To analyze this evolutionary event, nucleotide sequences of the Odh (Octanol dehydrogenase) gene were obtained for 43 lethal chromosomal lines from colonizing populations of North America and 5 from South America, in addition to 5 chromosomal lines from Europe with different viabilities and 2 from laboratory marker stocks. Since 10 different Odh haplotypes were found in America, the minimum number of colonizers would be 5 (or 3 mated females). Only one Odh haplotype was found in American O(5) inversions confirming that only one copy of this inversion was included among the sample of colonizers. The same Odh haplotypes were detected in association with the same chromosomal arrangements and with identical lethal genes in both North and South America indicating that exactly the same chromosome types reached both hemispheres. These observations indicate that the two continental colonizations are not independent. They are derived from the same colonization event. The population from which the colonization started should contain the O(5) inversion, a non-negligible frequency of the O(3+4+7) arrangement and all other arrangements found in America. So far the only populations that fulfill all these requirements are those from Greece, indicating that these populations can be considered good candidates as a starting point for an in depth analysis of the origin of the American colonization by D. subobscura.

GEM, a cluster of repetitive sequences in the Drosophila subobscura genome

GEM is a new family of repetitive sequences detected in the D. subobscura genome. Two of the four described GEM elements encompass a heterogeneous central module, with no detectable ORF, flanked by two long inverted repeats. These elements are composed of a set of repetitive modules, which are inverted repeat (IR), direct repeat (DR), palindromic sequence (PS), long sequence (LS) and short sequence (SS). These five modules can be found either clustered or dispersed as single modules in the D. subobscura genome, in euchromatic and heterochromatic regions. In addition to the 3' region of Adh retrosequences, single IR and LS blocks were found associated with the promoter region of different genes, in particular, LS-like blocks have also been found associated with functional genes in D. melanogaster and D. virilis. Conversely, the DR block is highly similar to satellite DNAs from some other species of the obscura group. In addition, GEM elements share some structural features with IS elements described in different Drosophila species. It is likely that both GEM and IS sequences would be vestiges of an ancestral transposable element.

Structure of the Drosophila melanogaster glutathione-dependent formaldehyde dehydrogenase/octanol dehydrogenase gene (class III alcohol dehydrogenase). Evolutionary pathway of the alcohol dehydrogenase genes

The glutathione-dependent formaldehyde dehydrogenase gene (gfd) of Drosophila melanogaster encodes an enzyme that is active toward S-hydroxymethylglutathione, an adduct of formaldehyde with glutathione, and also with long-chain primary alcohols, both properties typical of class III alcohol dehydrogenases, gfd hybridizes at the 86D division of the third chromosome, in agreement with the known location of the Drosophila octanol dehydrogenase gene (odh), gfd/odh was isolated from a lambda EMBL-4 genomic library and consists of three exons (with coding segments of 21, 90 and 1029 bp) and two introns (69 bp and 70 bp, respectively). The introns are small in size like the Drosophila interrupting sequences and are located at the 5' end of the coding region. Comparisons with the homologous genes of Saccharomyces, Candida and humans provide information on the evolution of the class III alcohol dehydrogenases. Moreover, results from analysis of exon/intron distributions in eleven dehydrogenases are compatible with the hypothesis of intron loss accounting for aspects of the present structure of these genes.

Chromosomal homologies between Drosophila lebanonensis and D. melanogaster determined by in situ hybridization

Twelve biotin-labelled recombinant DNA probes were hybridized to polytene chromosomes of Drosophila melanogaster and D. lebanonensis. Probes were chosen in order to cover the whole chromosomal complement. Six probes correspond to known genes from D. melanogaster (RpII215, H3-H4, MHC, hsp28/23, hsp83, hsp70), four probes are clones isolated from a D. subobscura library (Xdh, lambda DsubS3, lambdaDsubG3, lambdaDsubG4) and the remaining two probes correspond to the Adh gene of D. lebanonensis and to one sequence (262), not yet characterized, from the same species. The chromosomal homologies obtained from the in situ hybridization results allow us to determine that Muller's C and D chromosomal elements are fused in the karyotype of D. lebanonensis and constitute the large metacentric chromosome. Single pericentric inversions in the E and B elements have generated the medium and small metacentric chromosomes, respectively. No great changes are detected in Muller's A element, which remains acrocentric. The changes detected in the karyotypic evolution of D. lebanonensis are frequently observed in Drosophila evolution, as deduced from chromosomal homologies of several Drosophila species. The results are also consistent with Muller's proposal that chromosomal elements have been conserved during the evolution of Drosophila.

Adh and Adh-dup sequences of Drosophila lebanonensis and D. immigrans: interspecies comparisons

We have cloned and sequenced the Adh genomic region of Drosophila lebanonensis (subgenus Scaptodrosophila) and D. immigrans (subgenus Drosophila). This region, which contains Adh, encoding the alcohol dehydrogenase enzyme, and Adh-dup (duplicate of Adh), has been compared with the same fragment from D. subobscura (subgenus Sophophora). Even though the flanking regions and introns of both genes have been affected by high substitution rates, the consensus sequences have been clearly identified. Although the overall homology of the coding regions was 76-78% among the species compared, there were differences in the exon distribution of the nucleotide substitutions when Adh or Adh-dup were compared, thus showing that these two genes differ in their evolutionary pattern.

Evidence for retrotranscription of protein-coding genes in the Drosophila subobscura genome

Evidence is provided for the presence of retrosequences (also named retroposons) arising from Adh in the Drosophila subobscura genome. Restriction analysis and primary structure of two different retrosequence-containing clones, S812 and S135, are reported. The fact that these retrosequences lack introns and a recognizable promoter strongly supports their retrotranscriptional origin. Adjacent to the two retrosequences analyzed, a middle repetitive DNA element has been found which bears no clear similarity to any sequence reported to date in the GenBank/EMBL Data Library. A comparative analysis of these retrosequences with the functional Adh gene of D. subobscura is presented. In addition, a model concerning the origin, functionality, and propagation of these genome elements is discussed.

The Adh genomic region of Drosophila ambigua: evolutionary trends in different species

The study of individual genes is essential to a comprehensive understanding of genome evolution. The wealth of information on alcohol dehydrogenase (Adh) in Drosophila makes this gene particularly suitable for such analysis. We have characterized more than 4 kb of the genomic Adh region in Drosophila ambigua and compared this region to Drosophila mauritiana and Drosophila pseudoobscura. The presence of two genes, Adh and 3'ORF (open reading frame), has been confirmed and some of their essential features have been inferred from primary structural analysis. Inter- and intraspecific comparisons have led us to support that both genes may have diverged from an ancient precursor. They appear to be evolving independently, and show a species-specific pattern. The Adh in the obscura group species lacks amino acids three and four when compared to the species of the melanogaster group and has accumulated most of its amino acid replacements in the third exon. Neither characteristic is observed when any other group species are compared, which suggests that these may be particular features of the evolution of the obscura group. The 3'ORF is highly conserved among the three species analyzed, although variability in the length of the third exon and the nucleotide substitution rate, which is much higher than in Adh, are worth noting. According to our data, both mutation/fixation rates and the distribution of mutations vary over time, which makes it difficult to predict the evolutionary dynamics of specific genome regions.